WO2019166345A1

WO2019166345A1 - Voltage converter having coupled pfc choke

Info

Publication number: WO2019166345A1
Application number: PCT/EP2019/054472
Authority: WO
Inventors: Manuel Raimann; Daniel Weida
Original assignee: Bayerische Motoren Werke Aktiengesellschaft
Priority date: 2018-03-01
Filing date: 2019-02-22
Publication date: 2019-09-06
Also published as: US20200412272A1; CN111727551A; CN111727551B; DE102018203054A1

Abstract

The invention relates to a voltage converter (100), which is designed to convert an alternating input voltage into a direct output voltage. The voltage converter (100) comprises a first sub-converter having a first switch half-bridge (110), which is coupled to a first pole of the input voltage by means of a first main coil (141), and a second sub-converter having a second switch half-bridge (120), which is coupled to the first pole of the input voltage by means of a second main coil (142). In addition, the voltage converter (100) comprises a diode half-bridge, which is jointly used by the first sub-converter and the second sub-converter. Furthermore, the voltage converter (100) comprises a first back coil (143) and a second back coil (144), which couple a center point of the diode half-bridge to a second pole of the input voltage. The first and second main coils (141, 142) and the first and second back coils (143, 143) form a coupled choke (140), the coupled choke (140) having a choke core (200). The choke core (200) has at least one outer leg (201), which is surrounded by windings of the first and/or second main coil (141, 142) and/or of the first and/or second back coil (143, 143), and at least one center leg (202), which is not surrounded by windings of the main coils (141, 42) or of the back coils (143, 143). The outer leg (201) and the center leg (202) have materials having different permeabilities.

Description

Voltage transformer with coupled PFC choke

The invention relates to a polyphase voltage converter, in particular a rectifier, with a coupled inductor as a power factor correction filter.

In an AC / DC converter or rectifier, e.g. for a charger of an at least partially electrically powered vehicle which is connected to a public power grid, is typically a

Power Factor Correction (PLC) level used to maintain line connection conditions (especially in terms of limited power)

Harmonic components in the mains current). In particular, multi-phase PLC voltage converters may be used, such as e.g. a so-called totem-pole converter. The individual chokes of a multi-phase PPC voltage converter can be designed as coupled chokes. By using a multi - phase voltage converter with coupled chokes, the

Ripple current can be reduced.

A polyphase voltage converter has semiconductor switches (particularly gallium nitride, GaN, transistors) which are switched at a relatively high frequency (e.g., at 1 MHz and above). By switching the

Semiconductor switches can cause common mode (CM) and differential mode (DM) disturbances, which typically need to be compensated through a multi-stage line filter to meet line side EMC (Electromagnetic Compatibility) requirements.

The present document deals with the technical problem of reducing the common-mode noise of a polyphase voltage converter, in particular to simultaneously reduce the weight, the cost and the installation space for the PPC throttle and thus for a charger of a vehicle. The object is solved by the independent claim. advantageous

Embodiments are described i.a. in the dependent claims. It should be noted that additional features of one of

independent claim dependent patent claim without the features of the independent claim or only in combination with a subset of the features of the independent claim own and of the combination of all features of the independent claim

independent invention, which may be the subject of an independent claim, a divisional application or a subsequent application. This applies equally to technical teachings described in the specification, which may form an independent invention of the features of the independent claims.

According to one aspect, a voltage converter, in particular a rectifier, is described, which is set up to convert an AC input voltage into a DC output voltage. The voltage converter may be part of a charger, in particular a charger of a

Road car. The voltage converter comprises a first sub-converter with a first switch half-bridge, wherein the first switch half-bridge via a first half-bridge

Main coil is coupled to a first pole of the input voltage. The first switch half-bridge may comprise a first switch and a second switch arranged in series between a positive pole and a negative pole of the

Output voltage are arranged. The first main coil may then couple a mid-point between the first switch and the second switch of the first switch half-bridge to the first pole of the input voltage. The switches of the first switch half-bridge can each be designed as gallium nitride (GaN) transistors.

Furthermore, the voltage converter comprises a second sub-converter with a second switch half-bridge, which has a second main coil with the first pole the input voltage is coupled. Analogously to the first switch half-bridge, the second switch half-bridge may also comprise a first switch and a second switch, which are arranged in series between the positive pole and the negative pole of the output voltage. The second main coil may then couple a mid-point between the first switch and the second switch of the second switch half-bridge to the first pole of the input voltage. The switches of the second switch half-bridge can each be designed as gallium nitride (GaN) transistors. Additionally, the voltage converter includes a diode half-bridge shared by the first sub-converter and the second sub-converter. The diode half-bridge may comprise a first diode and a second diode arranged in series between the positive pole and the negative pole of the output voltage.

The voltage converter further includes a first rewind and a second rewind coupling a center of the diode half-bridge to a second pole of the input voltage. In other words, a part of the inductance of the first sub-converter and a part of the inductance of the second sub-converter can be laid as rewinding in the return path of the sub-converter. This allows common mode disturbances of the voltage converter to be reduced. The inductance of a main coil may be equal to or greater than the inductance of a corresponding rewind. For example, the ratio between the inductances of the main coil and the rewind can be in a range between 1: 1 and 5: 1.

The first and the second part converters can each be designed as rectifiers. In this case, in the context of the rectification function a

Voltage up conversion done. During a positive half wave of the input voltage, the first switch of a sub-converter can be clocked, while the second switch is operated as a diode. Furthermore, during a negative half cycle of the input voltage, the second switch a partial converter clocked and the first switch is operated as a diode. A sub-converter can thus be operated both during a positive half-wave and during a negative half-wave as an outward or boost converter. In this case, by reversing the operation of the switch of the switch half-bridge of a partial converter, the rectification function can be effected.

Typically, the frequency of the AC input voltage is 50Hz or 60Hz. The clocked operation of a switch can be in a frequency range of lOOkHz, lMHz or more.

The first sub-converter and the second sub-converter may be operated out of phase with each other with respect to the timing of the switches of the first and second switch half-bridges. The phase shift may be e.g. at 180 °. By using several (possibly phase-shifted) partial transducers, the voltage of the voltage converter can be increased. Furthermore, ripples of the output voltage and / or the output current of the

Voltage converter can be reduced.

The first main coil and the second main coil may form a common, coupled choke in combination with the first rewind and the second rewind. In this case, the coupled throttle has a common

Throttle core on. The throttle core comprises at least one outer leg and at least one middle leg. The at least one outer leg is enclosed by turns of the first and / or second main coil and / or the first and / or second rewind. On the other hand, that is at least one

Center leg not enclosed by turns of main coils and rewinds. In particular, the middle leg can not be enclosed by turns. In this case, the at least one outer leg and the at least one

Mittelschenkel materials, each with different permeabilities or permeability on. In particular, the material of the outer leg have a permeability greater than a permeability of the material of the center leg. For example, the permeability (in particular the permeability number) of the material of the outer leg may be greater than the permeability (in particular the permeability number) of the middle leg by a factor of 10, 100 or more. Furthermore, the material of the at least one outer limb and the material of the at least one center limb may each have a permeability number of 10, 20 or more (eg in each case at least be ferromagnetic). For example, the material of the outer leg may comprise nanocrystalline and / or ferrite. The material of the center leg may include ferromagnetic Metallkömer and / or a ferromagnetic powder.

It is thus described a (multi-phase) voltage converter having a common, magnetically coupled throttle, with a Drosselkem with different permeable areas. This allows common mode disturbances of the voltage converter to be reduced. In particular, the

Permeability numbers of the different regions of the throttle body are selected (e.g., in the course of experiments) to reduce the common mode noise, in particular to minimize and / or to reduce the packaging space of the throttle core. Thus, the complexity of a line filter to meet EMC requirements can be reduced, so that the size, space and weight of a charger that includes the voltage converter, can be reduced.

The permeability of the at least one outer limb and / or the at least one center limb is preferably substantially homogeneous over the entire spatial extent of the outer limb and / or the middle limb.

In particular, the throttle core can only have two different regions (the region of the one or more outer limbs and the region of the one or more middle limbs), each of which has a substantially homogeneous permeability. Thus, the efficiency of Drosselkems can be further increased. The throttle core may have a first outer leg and a second outer leg

Exterior leg include, wherein the first outer leg through the

Windings of the first main coil and extends through the windings of the first rewind, and wherein the second outer leg extends through the windings of the second main coil and through the windings of the second reel. In other words, the first outer leg may pass through the first main coil and through the first rewind. On the other hand, the second

Outboard leg through the second main coil and through the second main coil.

The first outer leg and the second outer leg can one

form a continuous, substantially homogeneous magnetic path for a main magnetic flux passing through all the turns of the first and second main coils and the first and second rewinds. In particular, the first outer leg and the second outer leg can each be C-shaped and together form a magnetic circuit for the

forming magnetic main flux.

On the other hand, the center leg may form a magnetic path for a magnetic flux passing through only a part of the turns of the first and second main coils and the first and second rewinds. The middle leg can run at least partially parallel to the first and second outer leg. Furthermore, both ends of the center leg may be in direct contact with the circuit formed by the outer legs. In particular, a substantially homogeneous magnetic path may be formed by the center leg from a first point to a second point of the magnetic circuit (as a kind of short circuit of the magnetic circuit for the main magnetic flux), e.g. to further reduce the degree of common mode noise.

In another aspect, a charger is described that includes the voltage converter described in this document. In another aspect, a road vehicle (especially a passenger car or a truck or a bus or motorcycle) is described that includes the voltage converter described in this document and / or the charger described in that document.

It should be understood that the devices and systems described herein may be used alone as well as in combination with other devices and systems described in this document. Furthermore, any aspects of the devices and systems described in this document may be combined in a variety of ways. In particular, the features of the claims can be combined in a variety of ways. Furthermore, the invention will be described in more detail with reference to exemplary embodiments. Show

FIG. 1 shows an exemplary multiphase voltage converter with a coupled PFC choke; and

2 shows an exemplary multi-part coil core for a coupled PFC throttle.

As stated at the outset, this document deals with the

Reduction of CM or common mode noise in a multi-phase voltage transformer. 1 shows an exemplary two-phase rectifier 100 having a first transistor half-bridge 110 for a first partial rectifier and a second transistor half-bridge 120 for a second partial rectifier. The two partial rectifiers are operated, for example, with a phase shift of 180 ° (with respect to the clock cycle of the switches Sn, Si ₂ , S21, S22 of the transistor half-bridges 110, 120). Furthermore, the rectifier 100 has a diode half-bridge 130 (with the diodes S _NI and S _N 2) and a coupled inductor 140 with partial coils 141, 142, 143, 144. The rectifier 100 is set up an AC (Altemating Current)

Input voltage V _IN to a DC (direct current) output voltage Vo to convert. In this case, the first partial rectifier forms a positive half-wave of the input voltage via the first main coil Li 141 with the clocked first switch Sn and operated as a diode second switch Si ₂ a

Boost converter. This applies in a corresponding manner for the second partial rectifier with the second main coil L ₂ 142. At a negative half wave of the input voltage of the first partial rectifier forms over the first

Main coil Li 141 with the clocked second switch Si ₂ and operated as a diode first switch Sn an up-converter. This applies in a corresponding manner to the second partial rectifier. This allows efficient rectification with active power factor correction.

The common mode noise can be reduced by routing a portion of the inductors of the sub-rectifiers into the return path of the sub-rectifiers, with the return path extending from the midpoint of diode half bridge 130 to the second pole of the input voltage. In particular, the rectifier 100 may have a rewinding L ₃ 143 and a rewinding L ₄ 143, the main reels 141, 142 and the rewinds 143, 144 being magnetically coupled together. By reducing the common mode noise, a line filter can be scaled down to filter these disturbances, reducing the size, cost, and weight of a charger that can handle the same

Rectifier 100 includes, can be reduced. FIG. 2 shows an exemplary coupled throttle 140 for a rectifier 100. In this case, the throttle 140 has a multipart coil or throttle core 200. In particular, the choke core 200 has outer legs 201, wherein a first outer leg 201 is enclosed by the turns of the first main coil 141 and the first rewind 143, and a second outer leg 201 of the turns of the second main coil 142 and the second rewind

144 is enclosed. The outer legs 202 are magnetically connected to each other to conduct a main magnetic flux 211, which turns all the turns the coils 141, 142, 143, 144 passes. For this purpose, the

Outer leg 202 may be C-shaped, and connected to each other so that there is a homogeneous magnetic circuit for the main magnetic flux 211.

The throttle core 200 includes a center leg 202 which is the two

External limb 201 short-circuits and is enclosed by none of the turns of the coils 141, 142, 143, 144. The center leg 202 conducts a magnetic (stray) flux 212, which does not pass all the turns of the coils 141, 142, 143, 144 of the coupled inductor 140. The ends of the middle leg

202 may be directly connected to an outer leg 201, respectively, such that the magnetic path for the (stray) flow 212 only at the (two) junctions between an outer leg 201 and the middle leg 202

Inhomogeneity in terms of permeability has.

The outer legs 201 and the middle leg 202 of the throttle body 200 may have different materials with different properties. In particular, in the outer magnetic path (i.e., in the

Outer legs 201) a highly permeable core material (e.g.

Nanocrystalline and / or ferrite), since this is advantageous for the coupling of the windings of the coils 141, 142, 143, 144 and thus for the reduction of the current ripple in the inductor 140 and thus for the reduction of the losses in the inductor 140. For the internal magnetic path (i.e., center leg 202), a low permeability core material (e.g., a powder core) may be used to optimize this portion of the magnetic energy storage choke 200.

By using different materials for different areas of the throttle body 200, an independent optimization of the

Throttle parameters are used to further reduce common mode transients. Thus, a line filter for filtering common-mode currents can be further reduced to reduce the cost, space and weight of chargers.

The present invention is not limited to the embodiments shown. In particular, it should be noted that the description and figures are intended to illustrate only the principle of the proposed devices and systems.

Claims

claims

1) a voltage converter (100) configured to convert an AC input voltage into a DC output voltage; wherein the voltage converter comprises (100)

- A first part converter having a first switch half-bridge (110) coupled via a first main coil (141) to a first pole of the input voltage;

- A second sub-converter having a second switch half-bridge (120) coupled via a second main coil (142) to the first pole of the input voltage;

a diode half-bridge shared by the first sub-converter and the second sub-converter;

- a first rewind (143) and a second rewind (144) coupling a midpoint of the diode half-bridge to a second pole of the input voltage; wherein the first and second main coils (141, 142) and the first and second rewinds (143, 143) form a coupled choke (140); wherein the coupled throttle (140) comprises a throttle core (200); wherein the throttle core (200) has at least one outer limb (201) surrounded by turns of the first and / or second main coil (141, 142) and / or the first and / or second rewinds (143, 143), and at least one Center leg (202), which is not enclosed by turns of the main coils (141, 142) and the rewinds (143, 143); the outer leg (201) and the

Central leg (202) materials each having different permeabilities.

2) voltage transformer (100) according to claim 1, wherein

- The material of the outer leg (201) has a permeability which is greater than a permeability of the material of the center leg (202); and the permeability of the material of the outer leg (201)

in particular by a factor of 10, 100 or more greater than the permeability of the center leg (202), 3) voltage transformer (100) according to one of the preceding claims, wherein

the material of the outer leg (201) and the material of the

Central leg (202) each having a permeability of 10, 20 or more; and or

a permeability of the outer leg (201) and / or the

Central leg (202) is substantially homogeneous over the entire spatial extent of the outer leg (201) and / or the center leg (202).

4) Voltage transformer (100) according to one of the preceding claims, wherein - the material of the outer leg (201) comprises nanocrystalline and / or ferrite; and or

- The material of the central limb (202) comprises ferromagnetic Metallkömer and / or a ferromagnetic powder. 5) voltage transformer (100) according to one of the preceding claims, wherein

- The Drosselkem (200) comprises a first outer leg (201) and a second outer leg (201);

- The first outer leg (201) by turns of the first

Main coil (141) and the first rewind (143) extends; - The second outer leg (202) by turns of the second

Main coil (142) and the second rewind (144) extends; and

the first outer leg (201) and the second outer leg (201) form a contiguous, substantially homogeneous, magnetic path for a main magnetic flux (211) comprising all turns of the first and second main coils (141, 142) and the first and second rewinds (143, 143) passes through.

6) A voltage converter (100) according to claim 5, wherein the center leg (202) forms a magnetic path for a magnetic flux (212), which only a part of the turns of the first and second main coil (141, 142) and the first and second rewind (143, 143) goes through.

7) voltage transformer (100) according to one of claims 5 to 6, wherein

- The center leg (202) at least partially parallel to the first and second outer leg (201) extends; and or

- The first outer leg (201) and the second outer leg (201) are each C-shaped and together form a magnetic circuit; and

- Both ends of the central limb (202) are in direct contact with the circuit formed by the outer legs (201) and form a substantially homogeneous magnetic path from a first region to a second region of the magnetic circuit.

8) voltage transformer (100) according to one of the claims, wherein

- The switch half-bridge (110, 120) of a partial converter comprises a first switch (Sn, S21) and a second switch (S12, S22) connected in series between a positive pole and a negative terminal of the

Output voltage are arranged; and

- The main coil (141, 142) of a sub-converter a center

between the first switch (S11, S21) and the second switch (S12, S22) is coupled to the first pole of the input voltage.

9) voltage transformer (100) according to claim 8, wherein

- During a positive half cycle of the input voltage of the first switch (S11, S21) of a partial converter clocked and the second switch (S12, S22) is operated as a diode; and - During a negative half cycle of the input voltage of the second switch (S ₁₂ , S ₂₂ ) of a partial converter clocked and the first switch (S ₁₁ , S ₂₁ ) is operated as a diode. 10) A voltage converter (100) according to one of the preceding claims, wherein the first sub-converter and the second sub-converter phase-shifted with respect to a clock of switches (S ₁₁ , S ₂₁ , S ₁₂ , S ₂₂ ) of the first and second Switch half bridges (110, 120) are operated.